Comsol > Case Studies > Capacitively Coupled Plasma Analysis

Capacitively Coupled Plasma Analysis

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Customer Company Size
SME
Region
  • America
Country
  • United States
Product
  • COMSOL Multiphysics
Tech Stack
  • Multiphysics Simulations
  • Two-term Boltzmann Approximation
Implementation Scale
  • Pilot projects
Impact Metrics
  • Innovation Output
  • Productivity Improvements
Technology Category
  • Analytics & Modeling - Digital Twin / Simulation
  • Analytics & Modeling - Predictive Analytics
Applicable Industries
  • Semiconductors
  • Electronics
Applicable Functions
  • Product Research & Development
Use Cases
  • Process Control & Optimization
  • Digital Twin
Services
  • Software Design & Engineering Services
  • System Integration
About The Customer
AltaSim Technologies, based in Columbus, Ohio, specializes in advanced simulation technologies. The company focuses on providing high-fidelity simulations for complex physical phenomena, including plasma processes. AltaSim Technologies employs a team of experts in various fields of engineering and physics to deliver cutting-edge solutions for their clients. Their expertise in multiphysics simulations allows them to tackle challenging problems in industries such as semiconductors and electronics. By leveraging tools like COMSOL Multiphysics, AltaSim Technologies aims to enhance the development and optimization of advanced manufacturing processes.
The Challenge
The multiphysics nature of plasmas presents enormous challenges for numerical simulations; analysis of the CCP process presents added difficulty due to the existence of a plasma sheath, the dynamic behavior of the plasma, and the large number of RF cycles required to reach a periodic steady state. Power deposition into the plasma is highly non-linear and the strong gradient of the electric field in the plasma sheath may lead to numerical instabilities unless a sufficiently fine mesh is applied. Typical CCP reactors may also contain sharp geometric corners that can cause a substantial local electric field that provide unphysical ion fluxes.
The Solution
AltaSim Technologies has performed one- and two-dimensional simulations of low-frequency RF discharges in axisymmetric CCP reactors for Maxwellian and non-Maxwellian cases using COMSOL Multiphysics. Electron transport properties and Townsend coefficients were calculated using the two-term Boltzmann approximation as a preprocessing step to the numerical analysis of the plasma. Ion densities are shown in Figure 1 for a 1D simulation of a non-Maxwellian plasma. Extensions of the model to analyze the plasma behavior for a Maxwellian plasma in a 2D case are shown in Figures 2 and 3. The simulations incorporate the multiphysics nature of plasmas and consequently can be used to assist with the development of new CCP processing technology.
Operational Impact
  • AltaSim Technologies successfully performed one- and two-dimensional simulations of low-frequency RF discharges in axisymmetric CCP reactors.
  • The simulations incorporated the multiphysics nature of plasmas, addressing the challenges posed by plasma sheaths and dynamic behavior.
  • Electron transport properties and Townsend coefficients were calculated using the two-term Boltzmann approximation, enhancing the accuracy of the simulations.
  • The results provided insights into ion densities for both Maxwellian and non-Maxwellian plasmas, aiding in the development of new CCP processing technology.
  • The use of COMSOL Multiphysics allowed for detailed analysis and optimization of plasma behavior in CCP reactors.

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